Available online at www.CivileJournal.org  
Civil Engineering Journal   
  Vol. 6, No. 4, April, 2020 
  
 
  
 
 
Dynamic Identification of an Early 20th Century Civil 
Architectural Building 
 
a*
M. Bilal Bağbancı  
a Architecture Department, Architectural Faculty, Uludag University, Görükle-Bursa, Turkey. 
Received 04 December 2019; Accepted 25 February 2020 
Abstract 
Historical structures are important in terms of both original construction techniques and cultural heritage. Therefore, 
material properties, construction techniques and dynamic behaviours of these structures must be identified in order to 
preserve them in the future by restoration studies.  This study is aimed to serve as an example for similar buildings in the 
region whose walls were constructed using filled brick with lime mortar and constructed using both timber and 
reinforced concrete slabs. In this study, the plan layout, construction techniques and the material usage of the building 
were investigated in detail. The mechanical and dynamic properties such as compressive stress, elastic moduli, shear 
stress, natural frequencies and mode shapes of the building were determined in-situ by flat-jack, shear and vibration tests. 
The finite element model of the structure was prepared, and the modal analysis of the structure was performed. The 
calibration of the model was ensured according to the vibration test results. The results obtained from this study show us 
that in-situ tests are extremely important for the accuracy of finite element models. It has been determined that the 
mechanical test data can be used with over 80% success in finite element models. 
Keywords: Timber; Masonry; Construction Technique; Operational Modal Analysis; Mechanical Tests. 
 
1. Introduction 
The studied building is situated in the centre of the Edremit district. It was constructed in the first quarter of the 
20th century. The building is a modern architectural heritage in terms of its architectural features. The building has 
lots of values such as value of originality, value of rarity, economic value, social value, functional value and political 
value, as discussed by B. M. Feilden and J. Jokiletho [1]. The house, which gained its importance with the hosting of 
Mustafa Kemal Atatürk in 1934, is known as the Atatürk House in the collective memory of the district. 
In terms of historical features, today's codes and standards are not sufficient for the restoration of the masonry 
structures. The complexity of the structure, the diversity in the use of materials, the different construction techniques, 
the absence of knowledge about the changes in time and causes of damage throughout its existence are the important 
problems. The mechanical properties and dynamic characteristics of the building should be identified by in-situ tests. 
The most effective methods for identifying the mechanical properties of masonry structures are flat-jack and shear 
tests. In these tests, a flatjack is inserted in a cut slot in the mortar and displacements are continuously read while 
hydraulic oil pressure is inflated into the metal plate. These test methods have been used over a long time by 
researchers [2-4]. The most common experimental study for identifying the dynamic properties of masonry structures 
is the Operational Modal Analysis (OMA) test method. In this test method, the dynamic parameters such as natural 
frequencies, mode shapes and damping ratios are estimated from output-only responses. There are many studies using 
                                                        
* Corresponding author: mbilal@uludag.edu.tr 
http://dx.doi.org/10.28991/cej-2020-03091499 
 
© 2020 by the authors. Licensee C.E.J, Tehran, Iran. This article is an open access article distributed under the terms 
 and conditions of the Creative Commons Attribution (CC-BY) license (http://creativecommons.org/licenses/by/4.0/). 
 
    
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the OMA technique to identify the dynamic parameters of masonry constructions [5-13].  
After performing the in-situ tests, the finite element model of the structure should be prepared in order to find out 
the structural behavior of the building. However, in many research studies, the finite element models did not 
accurately represent the real behavior of the structure. This was due to the estimation of the material properties without 
performing any in-situ tests. In some research studies, the material properties performed by test methods but vibration 
tests did not performed. For this reason, identifying the material properties and dynamic characteristics of the building 
gains importance before the finite element analysis of the building. The finite element model should be controlled and 
calibrated by comparing the modal analysis results and the in-situ vibration test results. After the calibration, the finite 
element model can represent the real behavior of the building. The mass participation factors, the mode shapes and the 
other structural analyses such as earthquake analysis, pushover analysis, etc. can be performed by using this model. In 
addition, the success of the flat-jack and shear test results is also investigated by the researchers.          
In the first part of the paper, the methodology of the research is explained with a flowchart. This is followed by the 
expression of the plan, construction techniques and material usage of the building. After this, the mechanical properties 
and dynamic characteristic of the building are investigated by using in-situ tests. The modal analysis is performed 
using a finite element analysis program. After the calibration of the finite element model, the mode shapes, natural 
frequencies and mass participation factors are presented in tables and the results are discussed in the conclusion part.     
2. Research Methodology  
In this study, the plan layout, construction techniques and material usage of the building were investigated on-site 
and the mechanical properties such as compressive stress, elastic moduli and shear stress of the masonry walls were 
investigated by using in-situ flat-jack and shear tests. The dynamic characteristics such as mode shapes and natural 
frequencies of the structure were analyzed by using in-situ vibration tests. The OMA test method was used for 
determining the dynamic characteristics of the structure. The finite element model of the structure was prepared, and 
the modal analysis of the structure was performed by using the ALGOR finite element program. The finite element 
model calibrations were done by comparing the frequencies obtained from the vibration tests and the finite element 
modal analysis. The process was repeated until the difference was under 10% and the finite element model was formed 
at the end. The flowchart of the study is presented in Figure 1. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 1. The flowchart of the study 
3. Plan, Construction Techniques and Material Usage 
The studied building, Edremit Atatürk House, is situated at the centre of the district. Edremit is a district of 
Balıkesir Province which is located in the north-west of Turkey and on the coast of the Aegean Sea. The building is 
situated on Çayiçi Street which is one of the most frequented streets in Edremit. The location of Edremit district and 
the studied house is presented in Figure 2.  
 
 
 
 
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Figure 2. Edremit district and the studied building (Google Earth) 
The house gained its importance with the hosting of Mustafa Kemal Atatürk in 1934. The construction of the house 
began in the first quarter of the 20th century according to the architectural features. After it was exposed to a fire in 
1991, the house was unavailable for use (Figure 3). Timber beams, timber slabs and the roof of the building collapsed 
after the fire. 
 
 
 
 
 
 
 
Figure 3. The studied building a) Outside view of the building b) Inside view of the building 
The house has three storeys; basement, ground floor and first floor. The house has a courtyard. The basement 
height is 2.10 m, while the ground and first floor heights are both 3.50 m. The basement floor plan can be seen in 
Figure 4. 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 4. The basement floor plan of the building 
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The walls of the building were constructed using brick material. Lime mortar was used as a binding material. Brick 
was used in the interior and exterior walls. The wall thicknesses are different for the exterior and interior walls. The 
exterior wall thicknesses are 50cm in the basement, and 40cm in the other storeys. The interior wall thicknesses are 
45cm in the basement, 30cm in the ground floor and 25cm in the first floor. Two different techniques were used in the 
slab constructions. Timber slab was used in the living areas, while reinforced concrete slab was used in the wet areas 
and the entrance of the building. It is believed that these two types of slabs were constructed at the same time because 
there were no construction joints in the intersection of the walls, and the slab elevations are equal. Despite the fire, the 
reinforced concrete slabs are intact today (Figure 5). 
 
 
 
 
 
 
 
 
 
 
 
Figure 5. The reinforced concrete slab in the entrance part of the building 
The reinforced concrete slab and timber slab usage in the construction of the building is shown in Figure 6. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 6. The reinforced concrete and timber slabs of the building 
4. The Mechanical Properties of the Brick Walls 
The mechanical properties such as compressive stress, shear stress and elastic moduli of the walls were investigated 
by using in-situ flat-jack and shear tests. The single flat-jack method was used for determining the compressive stress 
and elastic moduli of the walls. In this method, a flatjack is inserted in a cut slot in the mortar and displacements are 
continuously read while hydraulic oil pressure is inflated into the flatjack (Figure 7). The tests were conducted 
according to ASTM C1197 and ASTM C1314 [14, 15]. 
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Figure 7. The mechanical tests: Single flat-jack test 
The method C was used in the shear test according to ASTM C1531-09 [16]. In this method, the flatjack is 
horizontally inserted at one end of the test unit (Figure 8). The oil pressure is applied until the slip of the mortar 
occurs. 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 8. The mechanical tests: Shear test 
The average compressive stress, shear stress and elastic moduli of the walls are presented in Table 1. 
Table 1. Mechanical properties of brick walls 
2
Compressive stress 2.10 N/mm  
2
Shear stress 0.50 N/mm  
2
Elastic moduli 2750 N/mm  
5. Vibration Tests 
Vibration tests were conducted in-situ by placing sensitive accelerometers on the walls of the building. The 
Operational Modal Analysis test method was used to obtain the dynamic parameters of structure. Natural vibration 
frequencies and mode shapes were obtained by using this non-destructive test method.  
The dynamic parameters of the structure from output-only experimental data were found by this technique. The 
loads were environmental forces and the modal identification was based on responses only. The Dynamic Data 
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Acquisition/Structural Health Monitoring Device Testbox 2010 series data acquisition system was used in the study 
[17]. Six uniaxial accelerometers were used and for the accuracy of the tests, 20~30 minute test periods were applied. 
In the sensor placements, the perpendicular orientations were carefully checked for all walls. The sensors were placed 
on top of the first and second floor corners. Three sensors were placed on each floor. The orientations of the sensors 
on the plan view are shown in Figure 9.  
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 9. The sensor orientations on plan views a) Second floor b) First floor 
The placements of sensor number 5 and sensor number 6 on the second floor and the test equipment can be seen in 
Figure 10. 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 10. The sensor placements and the test equipment 
Frequency Domain Decomposition (FDD) was used in determination of the dynamic characteristics. The singular 
values of the spectral densities of the test setups are shown in Figure 11. The first mode frequencies can be seen in the 
figure. 
 
 
 
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Figure 11. The singular values of the spectral densities 
6. Finite Element Analysis 
The three-dimensional finite element model of the studied building was prepared using the Algor finite element 
analysis program [18]. The building is modeled using brick elements having three degrees-of-freedom at every node. 
The material properties of the walls were obtained from the experimental studies. After the finite element models were 
prepared, the modal analysis of the building was performed. The mode shapes, natural frequencies and mass 
participation factors were obtained from numerical analyses. The material properties and the boundary conditions were 
updated in order to represent the real behavior of the building which was obtained from the experimental vibration 
tests. 
The elastic moduli of the walls were taken with an average of 2250 N/mm2 after the calibrations. There is only an 
18% difference between the flat-jack test results. The first four mode shapes and the frequencies are presented in 
figure 12. The first mode is the displacement in the y direction, the second mode is the torsion, the third mode is the 
displacement in the x direction and the fourth mode is the torsion. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 12. The first four mode shapes and frequencies 
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The comparisons of the first four mode frequencies of the studied building between the vibration test results and the 
finite element analysis results after calibrations are presented in Table 2. It was determined that there was a maximum 
5% difference between the frequency values. It can be stated that the finite element model of the structure now 
represents the real behavior of the structure correctly. Earthquake analysis, pushover analysis, and etc. can be done by 
using this model. 
Table 2. First four mode frequencies (experimental vibration test versus finite element analysis) 
Mode Number Vibration test Finite element Error 
1 4.32 4.33 % 0.23 
2 4.93 4.73 % 4 
3 5.51 5.59 % 1.43 
4 6.20 5.86 % 5.48 
The mass participation factors of the first four modes in the x and y directions are presented in Table 3. Due to the 
lack of horizontal connections between the walls, the whole structure could not be completely included in the mass 
ratios. Therefore, the total mass participation ratios are low in the first four modes. 
Table 3. The mass participation factors of the first four modes in the x and y directions 
First mode Second mode Third mode Fourth mode 
x y x y x y x y 
0.12 31.11 0.20 1.32 14.50 0.75 0.46 0.09 
7. Conclusions 
Understanding the current status of historical buildings will enable them to be restored in a healthy way. The 
construction techniques, the material usage, the mechanical properties of the walls and the dynamic characteristics of 
the structure must be determined precisely. The finite element models must represent the real behavior of the structure. 
Finally, the structural behavior of the building in all load cases should be performed by computer analysis.  
Due to the unique construction techniques and material usages of each historical structure, the material properties 
obtained from the codes and standards are not sufficient for analysing a masonry structure. In some studies, the 
material properties of the structures were estimated by the researchers without any in-situ tests. Sometimes, the 
material properties were performed by test methods, but vibration tests were not performed. In all cases, the finite 
element models could not be sufficient for representing the real behavior of the structure. Only comprehensive on-site 
investigations and effective in-situ test methods can ensure the correct finite element models of the structure. 
In this study, the dynamic identification of an early 20th century civil architectural building was investigated by 
using on-site investigations, in-situ experimental tests and finite element analysis.  
The general conclusions of this study are outlined below. 
 To understand the construction techniques and the material usage of the structure is important to ensure the 
correct finite element model.   
 The flat-jack, shear and vibration tests were necessary to identify the mechanical and dynamic properties of the 
structure. 
 The finite element model must be calibrated by comparing the vibration test results with the modal analysis 
results.  
 There is only an 18% difference in elastic moduli values between the tests results and the calibrated finite 
element models. It can be stated that even if vibration tests are not performed, a close finite element model can 
be formed only with flat-jack and shear test data. 
 After calibration of the material properties, the errors between the vibration test results and the modal analysis 
ranged from a minimum of 0.23% to a maximum of 5.48%. These results show us that there was very good 
harmony between the frequencies and the finite element models. 
 Due to the lack of horizontal timber beams between the walls, about 20~30% of the whole structure could only 
be included in the mass ratios after the total of the first four mode frequencies. 
 A full understanding from on-site investigations, in-situ tests and the finite element analysis has great 
importance for the success of the restoration works. 
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8. Funding and Acknowledgement 
The financing of the restoration of the studied house was carried out by the Turkish Republic Municipality of 
Edremit. The restoration of the studied house began in January 2018 and was completed in November 2018. The 
author of this article worked as a civil engineering consultant until the beginning of the survey works at the end of the 
restoration of the house.  
9. Conflicts of Interest 
 The authors declare no conflict of interest.  
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